Astr 2310 Tues. Feb. 2, 2016

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1 Astr 2310 Tues. Feb. 2, 2016 Today s Topics Celestial Sphere Continued Effects due to Earth s Orbital Motion Apparent path of Sun across the sky Seasons Apparent Motions of Planets Complications Ancient Astronomy Babylonians and early culture Greeks Aristarchus Hipparcos Ptolemy 1

2 Celestial Sphere Continued Effects of Earth s Orbital Motion Sun s Apparent Path Across the Sky (Ecliptic and Zodiac) Origin of Seasons Annual Drift of Stars Analemma and the Equation of Time Complications Precession of Earth s Rotational Axis 2

3 Consequences of Earth s Orbital Motion Earth moves 360 o / days = 0.95 o /day Each day the Earth has to turn a little further for the Sun to rise Solar day = 24 hrs (time between successive sunrises) Siderial Day = 23 hr 56 min. (time between successive rises of a given star Stars rise slightly earlier each night creating a drift of the night sky over the course of 1 year 3

4 Motion of the Sun through the year Follow position of Sun relative to stars, over one full year. Each morning stars further east are revealed. Can determine day of the year (when to plant crops) by when a given star is seen. Over the course of 1 year the entire sky is visible. Apparent path of sun around the sky is called the ECLIPTIC Set of constellations through which it passes is called the ZODIAC From Horizons, by Seeds) 4

5 Plotting the Ecliptic on the Celestial Sphere The ecliptic is tilted relative to the celestial equator by 23.5 o From Horizons, by Seeds The sun is at the northernmost point on the ecliptic on June 22 a time and location called the SUMMER SOLSTICE The Sun is at the southernmost point on the ecliptic on Dec. 22 a time and location called the WINTER SOLSTICE The Sun just crossing the equator going N on March 21 a time and location called the VERNAL EQUINOX The Sun is just crossing the equator going S on Sept. 22 a time and location called the AUTUMNAL EQUINOX 5

6 Consider the Sun s daily motion thru the year Key point: Consider sun fixed at a given spot on ecliptic over the period of one day. From Horizons, by Seeds) At the Vernal Equinox Sun is on the celestial equator. At the Autumnal Equinox the Sun is also on the celestial equator. It rises due E, sets due W It is up exactly 12 hours At the Summer solstice Sun is a northern star. It rises N of E, sets N of W It is up more than 12 hours At the Winter Solstice it is a southern star It rises S of E, sets S of W It is up less than 12 hours 6

7 How the Sun s location affects the seasons: The angle of the sun s rays: In the summer it passes closer to overhead and therefore shines more directly on the summer hemisphere The time the Sun is up In the summer it spends more than 12 hours above the horizon. The seasons are NOT due to the slightly elliptical shape of the Earth s orbit and the fact that it is slightly closer to the Sun during part of the year. Test of that hypothesis: If the distance were the cause, then when it was summer in the northern hemisphere, what season would it be in the southern hemisphere? SUN (From our Text: Horizons, by Seeds) 7

8 Special Locations on the Earth How close to the North Pole do we need to go before the Summer Solstice sun becomes a circumpolar star and is above the horizon all day? Within 23.5 o of the pole: THE ARCTIC CIRCLE How close to the equator do we need to get before the Summer Solstice sun passes directly overhead rather than somewhat to the south: Within 23.5 o of the equator: The TROPICS (From our Text: Horizons, by Seeds) 8

9 Why are the planets found near the ecliptic? The ecliptic is defined by the plane of the Earth s orbit around the Sun. If the other planets are always found near the ecliptic, they must always be located near the plane of the Earth s orbit at most slightly above or below it. The planes of their orbits around the sun must almost match the Earth s. Their slight motions above and below the ecliptic means the match isn t exact. (Their orbits are slightly tilted relative to ours.) From our text: Horizons, by Seeds 9

10 Superior vs. Inferior Planets Superior planets (Mars, Jupiter, Saturn, Uranus, Neptune, Pluto) have orbits larger than the earth and can appear opposite the sun in the sky. They can be up at midnight. Never show phases. Inferior planets (Mercury, Venus) have orbits smaller than earth and can never appear far from the Sun. They form morning stars or evening stars visible a little before sunrise or after sunset. Show phases. From our text: Horizons, by Seeds 10

11 Apparent Motion of Inferior Planets Inferior planets (Mercury, Venus) have orbits smaller than earth and can never appear far from the Sun. They form morning stars or evening stars visible a little before sunrise or after sunset. If the inferior planet sets before the Sun it won t be visible in the evening sky. Look for it instead in the morning sky and vice versa. From our text: Horizons, by Seeds 11

12 Apparent Motion of Superior Planets Earth s Orbital Motion is Faster than that of the Outer Planets Change of perspective over time Superior planet appears to slow and even backup as the Earth passes it (Retrograde Motion) Very Difficult to Explain from Geocentric View 12

13 As Earth overtakes the slower supior planet the outer planet can appear to reverse its direction in the sky. Retrograde Motion 13

14 Earth Axis is Tilted and its Orbit is Elliptical Apparent path of the Sun across the sky depends upon the season. Elliptical orbit results in faster orbital speed of the Earth when closest to the Sun and slower speed when further. The position of the Sun at midday drifts E/W with respect to the Meridian. Sometimes behind and sometimes ahead of average. i.e., length of Solar day depends on day of year. Result is the Analemma and the Equation of Time 14

15 Analemma Photograph Sun at same time each day. 15

16 Highly enlarged view, sometimes shown on globes. Note the faster motion of the Earth in Dec/Jan when closest to the Sun and slower motion in Jun/July when we re furthest. 16

17 Equation of Time Drift can be expressed as a difference between the local apparent time and the mean solar time (averaged over the year). This correction is known as the Equation of Time 17

18 Complications: Precession of the Earth The earth s axis of rotation is tilted relative to the plane containing the sun and other planets (obliquity). The gravity from the Sun and moon is trying to tip the earth just like gravity is trying to tip a spinning top (torque). As with the top, the axis of the earth wobbles or PRECESSES in space, with a 26,000 year period. Because the directions to the celestial poles are defined by the spin axis those poles appear to move with time. It isn t that the stars move it is that the grid we paint on the celestial sphere has to be redrawn from time-totime. Polaris has not always been the pole star. Evident from Egyptian tomb paintings FromHorizons, by Seeds) 18

19 Ancient Astronomy Babylonians, Assyrians, Egyptians, Bronze-age British, Mayans, Polynesians Sophisticated knowledge of celestial motions and seasons. Developed calendars and predicted eclipses Chinese Long, detailed record of unusual events Comets Novae, supernovae All these cultures viewed universe as geocentric. How would the sky look if Sun and planets really did orbit the Earth? 19

20 Early Greek Astronomy Pillar of Western Thought for 2000 yrs Developed Concepts Still Used Today Constellations Star brightness classification (magnitudes) Planets Understood Phases of the Moon Discovered Precessional Motion Established Rough Scale of the Solar System First Application of Mathematics to Astronomy Developed a Quantitative Geocentric Perspective The universe is just what we perceive. Some suggested the Earth might orbit the Sun The universe not be all that it seems 20

21 Early Greeks and Their Contributions Plato B.C. Simple motion using spheres Perfection of the heavens, Eudoxus B.C. Retrograde motion Aristotle B.C. Shape of Earth, Multiple Spheres Aristarchus B.C. Heliocentric Model, Size of the Moon, Distance of the Sun Eratosthenes B.C. Size of the Earth Hipparchus B.C. Size of the Moon, Distance of the Sun. Star Catalogs, Stellar Magnitudes, Precession Ptolemy A.D. Models for planetary motion 21

22 The Sky Today Constellations: -Originally vague -Mostly Greek -Now well defined, including the southern hemisphere -Total of 88 to cover the sky Asterisms: -Less Formal Groups (Big Dipper) 22

23 Big Dipper The stars in a constellation or asterism like the Big Dipper are NOT necessarily at the same distances. These are just chance arrangements as seen from Earth. From Horizons, by Seeds 23

24 Names of stars Horizons, by Seeds) Orion Proper names mostly from Arabic astronomy Astronomers use (α, β, δ, ε,... ) + Constellation Name in approximate order of brightness Alpha Orionis = Betelgeuse Beta Orionis = Rigel Alpha Tauri = Aldebaran Numbers and other schemes for fainter stars. (About 6000 stars are visible to naked eye.) 24

25 Eclipses (1) Very Dramatic Significant to primitive cultures Religious significance Astrological meaning Long detailed records reveal patterns Eclipses can be predicted 25

26 Eclipses (2) Early Greeks were well aware of the phases of the moon and their origin Aristotle noted that the shape of the Earth s shadow during a lunar ecipse proved the Earth was round Eratosthenes measured size of Earth by measuring the position of the Sun from two locations at the same time. 26

27 Shadows and Eclipses Both the Earth and the Moon will cast shadows. If the Sun, Earth, and Moon are all lined up, then the shadow from one can fall on the other. Because the Earth is ~4 times bigger, it will cast a shadow 4 times bigger. From Horizons, by Seeds Umbra Portion of shadow where it is completely dark. (for a person in the shadow, the light bulb would be completely blocked out) Penumbra Portion of shadow where it is only partially dark. (for a person in the shadow, the light bulb would be partially blocked out) (To remember the names, think of ultimate and penultimate ) 27

28 Types of eclipses Lunar Eclipse Solar Eclipse We view the illuminated object and watch it go dark. Everyone on one side of the Earth can see the Moon so a given lunar eclipse is visible to many people. We view the illuminating object (the Sun) and see it blocked out. Only a few people are in the right place to be in the shadow (Moon and Sun are nearly the same size). It is coincidence that the umbra just barely reaches earth. From Horizons, by Seeds 28

29 Solar eclipses If you are outside the penumbra you see the whole sun. If you are in the penumbra you see only part of the sun, a partial eclipse. If you are in the umbra you cannot see any of the sun, a total eclipse. The fact that the moon is just barely big enough to block out the sun results from a coincidence: The sun is 400 times bigger than the moon, but also almost exactly 400 times further away. The orbit of the moon is elliptical. At perigee it can block out the full sun At apogee it isn t quite big enough, giving an annular eclipse, a ring. 29 From Horizons, by Seeds

30 Eclipse Facts Longest possible total eclipse is only 7.5 minutes. Average is only 2-3 minutes. Shadow sweeps across 1000 mph! Birds will go to roost in a total eclipse. The temperature noticeably drops. Totally predictable (even in ancient times, e.g., the Saros Cycle, eclipse pattern repeats every days or 18 years, 11 1/3 days). Stonehenge is thought to be a device for predicting eclipses. 30

31 Eclipses and Nodes From Horizons by Seeds. 31

32 Variations in Solar Eclipses Elliptical orbits mean angular size variation. Total Solar Eclipse Diamond-Ring Effect Annular Eclipse 32

33 Future Solar Eclipses A good web page for solar eclipses: eclipse.gsfc.nasa.g ov/eclipse.html eclipse.gsfc.nasa.g ov/semap/ SEmapNA/ TSENorAm2001.gi f The most favorable next Solar eclipse is August 21,

34 Phases of the Moon and its orbit around the Earth (1). 1. Everything (almost) in the solar system rotates or orbits counterclockwise, as seen from the North. 2. The illumination of the Earth and the moon will be almost the same, since the sun is so far away that both receive light from (almost) the same direction. 3. It takes 4 weeks for the moon to complete an orbit of the earth. 4. The moon is phase-locked. In other words, we always see the same face, although the illumination pattern we see changes. How long is a lunar day? From our text: Horizons, by Seeds 34

35 Phases of the Moon and its orbit around the Earth (2). From our text: Horizons, by Seeds Suppose you are asked when the first quarter moon will rise, when it will be overhead, and when it will set. Which side will be illuminated? If it is first quarter, it has moved ¼ revolution around from the new moon position, so it is at the top of the diagram. For a person standing on the earth, the moon would rise at noon, be overhead at 6 pm, and would set at midnight. It has to be the side towards the sun which is illuminated. Imagine yourself lying on the ground at 6 pm, head north, right arm towards the west. That west (right) arm points towards the sun. That must be the side which is illuminated. 35

36 Aristotle s Universe: Earth s Shape Aristotle knew the Earth was round: Shadow of Earth during lunar eclipse From our text: Horizons, by Seeds Changing height of Polaris and celestial pole as you moved south Eratosthenes measured size of Earth to better than 20% ~200 BC, Greek living in Alexandria Egypt Observed that Sun was overhead at Syene on summer solstice Sun was 7 o to the south of zenith at Alexandria Circumference of Earth must be 360/7 times distance from Syene to Alexandria From Voyages by Fraknoi et al. 36

37 Aristotle s Universe: Earth s Motion Aristotle had good reasons to think the Earth stood still: Absence of any detectable parallax If the Earth orbits the sun (rather than the reverse) then we should be able to see shifts in the positions of the stars due to parallax. From our text: Horizons, by Seeds The amount of parallax is proportional to Radius of Earth's orbit Distance to star We now know the distance to the nearest star is so large that even it only has a parallax of 1 second of arc = 1/3600 deg. 1 parsec = 3.26 ly. This is much too small to be measured with the naked eye. 37

38 Aristotle s Universe: Planets Motion Heavens composed of perfect fifth element Elements: Earth, Air, Fire, Water, Quintessence Heavens are unchanging except for rotation: Motion produced by multiple nested spheres Rotate at constant rate Are offset and inclined in ways to produce motion of planets Our Celestial Sphere of stars is just the outermost of many he had. VERY complicated for a perfect system! 38

39 Recall Retrograde Motion Planets stay almost on the ecliptic Most of the time they move East (relative to stars) Rates drop from Mercury to Venus to Mars to Jupiter to Saturn. Superior planets exhibit retrograde motion near opposition. 39

40 Eratosthenes and the Radius of the Earth (1) Eratosthenes hears Sun shines directly down a well in Syene on a particular day of the year, i.e., at zenith. On that day he notes that it is significantly south of the zenith at Alexandria. He knows the Earth is round from the shape of the Earth s shadow during an eclipse. He realizes he can now measure the Earth s radius. 40

41 Eratosthenes and the Radius of the Earth (2) Recall the arc-length formula ( s = rθ) So, D = R E θ if θ is in radians D = 5000 stadia (~ 800 km) θ = 7. o 2 = radian (Eratosthenes) R E = 800/ = 6364 km (actually 6378 km, so very close!) 41

42 Aristarchus and the Scale of the Solar System Aristarchus realized that the relative geometry of the Earth, Moon and Sun could be determined. Time between phases of the Moon give the distance of the Sun relative to that of the Moon Angular size of the Moon compared to that of the Earth s shadow gives the size and distance of the Moon relative to the Earth s radius. Given the Earth s radius (Eratosthenes) the scale of the Solar System can be computed. 42

43 Aristarchus continued (2) Aristarchus stated that the Moon appeared half-full when the angle between the Moon & Sun (θ) is 87 o. Sin φ = d M /d S How did he get θ = 87 o? One way might have been by measuring the time between moon phases: Sun (Time1 Time2)/period = 2(90 o - θ)/ 360 o = 2φ/360 o 1-st quart. 3-rd quart. θ = 87 o gives: d S = 19 d M Earth The real value is 400x! 43

44 Aristarchus continued (3) Aristarchus assumed: θ of Sun & Moon is 1/2 o. Earth s shadow is 8/3 θ M d S >> d M (d S ~ 400 d M ) From similar triangles: 2R E /l 1 ~ 2R S /d S = 2R M /d M (1) Sun ~ (8/3)(2R M )/l 2 Since: 2R M /d M = 16R M /3l 2 Moon Earth and d M = 3l 2 /8 and tan(0.25) ~ R E /l 1 ~ R M /d M so: l 2 l 1 l 1 = R E /tan(0.25) = 229 R E 44

45 Aristarchus continued (4) Continuing: l 1 = d M + l 2 = 3l 2 /8 +l 2 = 11l 2 /8 So: l 1 = l 2 = 229R E (2) l 2 = R E (3) Sun d M = l 1 l 2 = ( )R E d M = 62.3 R E (actually 60.2) From (1) and (2) we have: 8R E /11 l2 ~ 8R M /3l 2 so: Moon Earth R M ~ 3/11 R E (size of moon compared to the size of the Earth) Since we know R E and θ M we can determine d M along with R M. l 2 l 1 45

46 Aristarchus (summary) Aristarchus concluded: Sun is about 19 further away than the Moon (actually about 400 times further away!) Sun is about 7 times bigger than the Earth (actually about 109 times bigger!) Although his values are pretty far off the importance is the use of geometry and algebra to astronomy. Aristarchus also advocated a heliocentric theory for the Solar System. Aristotle had rejected this since stars don t show parallax. Aristarchus argued that this is simply because the stars are very far away and similar to the Sun. None of his writings survived so his work was mostly forgotten. 46

47 Hipparcos Improved the accuracy of Aristarchus methods Cataloged the position and apparent brightness of several hundred stars Stellar magnitude scale Realized that the Earth s axis precesses by comparing his catalog with previous, smaller, catalogs. At the time this was not appreciated or thought to be important. 47

48 Magnitudes (m) to denote brightness Ancient system created by Hipparchos 1 st magnitude = brightest stars in sky 6 th magnitude = faintest visible to naked eye Confusing because smaller number implies brighter (Think of first magnitude as first in class ) Astronomers want a numerical measure of Intensity (I) which is proportional to energy per unit time received from the star. Relationship between I and m turns out to be logarithmic (result of properties of human eye) 48

49 Numerical Relationship between m and I Every increase in m by 1 is a drop in brightness by a factor of We receive times less power from a 2 nd magnitude star than from a 1 st magnitude one. We receive = times less from a 3 rd magnitude than a 1 st magnitude We receive (2.512) 5 times less from a 6 th magnitude star than a 1 st magnitude. The 5 comes from 6-1. Because (2.512) 5 = 100 (not by accident) the faintest stars we can see are 100 times fainter than the brightest. 49

50 Apparent Visual Magnitude Scale From our Text, Horizons by Seeds 50

51 Formula for Intensity vs. m: I I A B = ( 2.512) m B m ( A With mathematics which we won t derive here, you can show this is equivalent to the equation: m m = A B 2.5log( I / I ) B A This second equation is easy to use on a calculator. If you remember that log( 10 n ) = n, for example log( 10 4 ) = 4, log (10 5 ) = 5, log(10 6 ) = 6, you can use it even without a calculator. ) Magnitude Difference , , , Intensity Ratio 15 1,000, ,000,000,000 51

52 Ptolemy Provided the only record of Hipparchos contributions (until recently) Expanded Hipparchos stellar catalog Explained retrograde motion by a complex set of nested circles (epicycles: wheels within wheels ) This system was complex but highly accurate. It was the accepted explanation for over 1000 years! In order to achieve a significant precision hundreds of epicycles were eventually needed. This complexity finally became too much. Demonstrated that precession was real and significant 52

53 Ptolemy s Evidence for Precession Compared the position of Spica with the equinox. Hipparchos noted that the star Spica was once visible at sunset on the autumal equinox. Ptolemy noted that Spica was now visible in the sky at sunrise at that date. Equinox was moving slowly along the ecliptic eastward. He calculated the rate that the drift of positions was occurring. Measured a drift of 2 o 40 since Hipparchos (265 yrs) The origin was a major mystery in astronomy 53

54 Ptolemy s explanation of retrograde motion: Epicycles From our text: Horizons, by Seeds Advantage: Could predict precise positions of planets Disadvantage: No physical explanation of why motion is like this Uses multiple levels of circular motion. Planet moves on a small circle called en epicycle. Center of epicycle moves on a larger circle called a deferent. Earth is fixed near (not exactly at) the center of the deferent. Motion around deferent is only constant as seen from point called equant. Add epicycles on epicycles to refine motion. 54

55 Homework this Week A2310 HW #1 Due Tuesday Feb. 9 Ryden & Peterson: Ch. 1: #2, #3, #4, #6, #8 Plus the following: Compute the approximate Sideral Times: a) midnight on June 20, b) 3 am on Sept. 20, c) 8 pm on Nov. 1, d) 6 am on March 20 55

56 Reading this Week By Next Thursday: Review Math, Appendix 9 (pg. A-20 - A-31) Review Celestial Sphere, Appendix 10 (pg. A-32 A-36) History of Astronomy: History_of_astronomy By Next Tuesday: Chapter 1 Celestial Mechanics At the end of each chapter study the Key Equations & Concepts. 56

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